- GitOps workflow steps
- GitOps configuration reference
- GitOps annotations
- Automatic drift remediation
- Related topics
- Troubleshooting
Using GitOps with a Kubernetes cluster
- Introduced in GitLab 13.7.
-
Introduced in GitLab 14.0, the
resource_inclusions
andresource_exclusions
attributes were removed andreconcile_timeout
,dry_run_strategy
,prune
,prune_timeout
,prune_propagation_policy
, andinventory_policy
attributes were added. - Moved from GitLab Premium to GitLab Free in 15.3.
-
Changed to make the
id
attribute optional in GitLab 15.7. - Specifying a branch, tag, or commit reference to fetch the Kubernetes manifest files introduced in GitLab 15.7.
With GitOps, you can manage containerized clusters and applications from a Git repository that:
- Is the single source of truth of your system.
- Is the single place where you operate your system.
By combining GitLab, Kubernetes, and GitOps, you can have:
- GitLab as the GitOps operator.
- Kubernetes as the automation and convergence system.
- GitLab CI/CD for Continuous Integration and the agent for Continuous Deployment.
- Built-in automatic drift remediation.
- Resource management with server-side applies for transparent multi-actor field management.
This diagram shows the repositories and main actors in a GitOps deployment:
For details, view the architecture documentation.
GitOps workflow steps
To update a Kubernetes cluster by using GitOps, complete the following steps.
- Ensure you have a working Kubernetes cluster, and that the manifests or Helm charts are in a GitLab project.
- In the same project, register and install the GitLab agent.
- Configure the agent configuration file so that the agent monitors the project for changes to the Kubernetes manifests. Use the GitOps configuration reference for guidance.
Any time you commit updates to your Kubernetes manifests, the agent updates the cluster.
GitOps configuration reference
The following snippet shows an example of the possible keys and values for the GitOps section of an agent configuration file (config.yaml
).
gitops:
manifest_projects:
- id: gitlab-org/cluster-integration/gitlab-agent
ref: # either `branch`, `tag` or `commit` can be specified
branch: production
# commit: <mysha>
# tag: v1.0
default_namespace: my-ns
paths:
# Read all YAML files from this directory.
- glob: '/team1/app1/*.yaml'
# Read all .yaml files from team2/apps and all subdirectories.
- glob: '/team2/apps/**/*.yaml'
# If 'paths' is not specified or is an empty list, the configuration below is used.
- glob: '/**/*.{yaml,yml,json}'
reconcile_timeout: 3600s
dry_run_strategy: none
prune: true
prune_timeout: 3600s
prune_propagation_policy: foreground
inventory_policy: must_match
Keyword | Description |
---|---|
manifest_projects
| Projects where your Kubernetes manifests are stored. The agent monitors the files in the repositories in these projects. When manifest files change, the agent deploys the changes to the cluster. |
id
| Path to a Git repository that has Kubernetes manifests in YAML or JSON format. No authentication mechanisms are supported. Default is the agent configuration repository. |
ref
| Optional. Git reference in the configured Git repository to fetch the Kubernetes manifest files from. If not specified or empty, the default branch is used. If specified, it must contain either branch , tag , or commit .
|
ref.branch
| Branch name in the configured Git repository to fetch the Kubernetes manifest files from. |
ref.tag
| Tag name in the configured Git repository to fetch the Kubernetes manifest files from. |
ref.commit
| Commit SHA in the configured Git repository to fetch the Kubernetes manifest files from. |
default_namespace
| Namespace to use if not set explicitly in object manifest. Also used for inventory ConfigMap objects.
|
paths
| Repository paths to scan for manifest files. Directories with names that start with a dot (.) are ignored.
|
paths[].glob
| Required. See doublestar and the match function for globbing rules. |
reconcile_timeout
| Determines whether the applier should wait until all applied resources have been reconciled, and if so, how long to wait. Default is 3600 seconds (1 hour). |
dry_run_strategy
| Determines whether changes should be performed. Can be: none , client , or server . Default is none .
|
prune
| Determines whether pruning of previously applied objects should happen after apply. Default is true .
|
prune_timeout
| Determines whether to wait for all resources to be fully deleted after pruning, and if so, how long to wait. Default is 3600 seconds (1 hour). |
prune_propagation_policy
| The deletion propagation policy that should be used for pruning. Can be: orphan , background , or foreground . Default is foreground .
|
inventory_policy
| Determines whether an inventory object can take over objects that belong to another inventory object or don’t belong to any inventory object. This is done by determining if the apply/prune operation can go through for a resource based on comparison of the inventory-id value in the package and the owning-inventory annotation (config.k8s.io/owning-inventory ) in the live object. Can be: must_match , adopt_if_no_inventory , or adopt_all . Default is must_match .
|
GitOps annotations
The GitLab agent for Kubernetes has annotations you can use to:
- Sort resources: Apply or delete resources in a specific order.
- Use apply-time mutation: Dynamically substitute fields from one resource configuration to another.
The agent has default sorting, but with annotations, you can fine-tune the order and apply time-value injection.
To provide the GitOps functionality, the GitLab agent for Kubernetes uses the cli-utils
library,
a Kubernetes SIG project. You can read more about the available annotations in the cli-utils
documentation.
Automatic drift remediation
Drift happens when the current configuration of an infrastructure resource differs from its desired configuration. Typically, this is caused by manually editing resources directly rather than via the used infrastructure-as-code mechanism. Minimizing the risk of drift helps to ensure configuration consistency and successful operations.
In GitLab, the agent for Kubernetes regularly compares the desired state from the git
repository with
the actual state from the Kubernetes cluster. Deviations from the git
state are fixed at every check. These checks
happen automatically every 5 minutes. They are not configurable.
The agent uses server-side applies.
As a result, every field in a resource can have different managers. Only fields managed by git
are checked for drift. This facilitates the use of in-cluster controllers to modify resources like
Horizontal Pod Autoscalers.
Related topics
- Deploying Helm charts with the GitOps workflow
- GitOps working examples for training and demos
- Self-paced classroom workshop (Uses AWS EKS, but you can use for other Kubernetes clusters)
- Managing Kubernetes secrets in a GitOps workflow
- Application and manifest repository example
Troubleshooting
Avoiding conflicts when you have multiple projects
The agent watches each glob pattern set under a project’s paths
section independently, and makes updates to the cluster concurrently.
If changes are found at multiple paths, when the agent attempts to update the cluster,
a conflict can occur.
To prevent this from happening, consider storing a logical group of manifests in a single place and reference them only once to avoid overlapping globs.
For example, both of these globs match *.yaml
files in the root directory
and could cause conflicts:
gitops:
manifest_projects:
- id: project1
paths:
- glob: '/**/*.yaml'
- glob: '/*.yaml'
Instead, specify a single glob that matches all *.yaml
files recursively:
gitops:
manifest_projects:
- id: project1
paths:
- glob: '/**/*.yaml'
Use multiple agents or projects
If you store your Kubernetes manifests in separate GitLab projects, update your agent configuration file with the location of these projects.